A self-leveling container that contains argon gas for laser welding of a work piece includes a base surface, a plurality of pleated sidewalls, each comprising an associated distal sidewall end and an associated proximate sidewall end, where the proximate sidewall end is sealed to the base surface. A frame includes a plurality of frame segments, each secured to an associated one of the distal sidewall ends. A plurality of actuators, each located with one intersection of the plurality of frame segments, linearly move its associated one intersection of the plurality frame segments so a plane formed by the frame segments remains parallel to a planar surface.

A laser machining head has a function of rectifying an assist gas and includes a protection window, a nozzle configured to blow the assist gas over a workpiece, a chamber defining a space between the protection window and the nozzle, an inflow port disposed in a chamber and configured to allow the assist gas to flow in, and a flow dividing projection disposed at a position opposing to the inflow port and configured to divide the assist gas from the inflow port into a first flow and a second flow flowing along a circumferential direction around an optical axis of a laser beam.

A laser cutting tool with protective enclosure assembly for manipulating a workpiece on a movable platen includes a frame, a top protection assembly, a middle protection shield, a bottom protection assembly and a laser torch head. The top protection assembly, middle protection assembly, and bottom protection assembly are removably mounted to the frame such that they form a cavity enclosing only substantially the laser torch head.

A laser machining device includes a storage unit configured to store a reference value based on an energy amount of returning light when laser light is emitted, in a state where external optical system is not contaminated, toward a reflection plate with a predetermined output low enough not to melt or deform the reflection plate such that a focus position of the laser light aligns with a predetermined position, and a processing condition correction unit configured to correct, prior to laser machining, a processing condition in accordance with the contamination level of the external optical system, wherein the processing condition correction unit includes a laser power correction section configured to correct a laser power of the processing condition based on the measurement value measured by a returning light measurement unit and the reference value.

A laser machining head includes a protection window disposed inclined with respect to an optical axis of a laser beam, an inflow port disposed downstream of the protection window and configured to allow a gas to flow in, and a flow dividing projection configured to divide the gas into a first laminar flow flowing along parallel to a surface of the protection window and a second laminar flow flowing toward a workpiece. The flow dividing projection is disposed in a position opposing to the inflow port with the optical axis of the laser beam as the center.

A laser remote processing system, in particular a laser remote welding system, has a laser cell surrounded by a protective housing, in which a working robot having a remote laser tool and a first processing station in the working region of the working robot are arranged. In order to improve the efficiency of the system, a second processing station in the working region of the working robot, and at least one handling robot are furthermore arranged within the protective housing, it being possible to reposition workpieces between the first processing station or the second processing station and a buffer region with the handling robot. The buffer region is set up to receive workpieces and is integrated into the protective housing as an automatably actuable workpiece lock.

Laser processing head (20) of the present disclosure includes housing (30), transparent protector (40), and temperature sensor (70). Housing (30) includes an optical path of processing laser light (LB). Transparent protector (40) is detachably fixed to housing (30), passes processing laser light (LB), and suppresses dust of work material (W) entering into housing (30). Here, the dust is generated from the work material (W) irradiated with processing laser light (LB). Temperature sensor (70) detects the temperature of transparent protector (40).

A laser processing device includes a beam splitter disposed between a focusing lens and a protective window, a return light measurement unit configured to measure intensity distribution of a return light reflected from a workpiece and returning to an external optical system via the beam splitter, a storage unit configured to store at least one of normal pattern data representing the intensity distribution of the return light when the protective window is in normal condition and abnormal pattern data representing the intensity distribution of the return light when the protective window is contaminated, a processing unit configured to perform a process of detecting contamination of the protective window during laser processing based on measurement data about the return light and at least one of the normal pattern data and the abnormal pattern data, and a warning unit configured to warn of contamination of the protective window in accordance with the process.

A laser welding device includes: a gun body mounted on a front end portion of an arm of a robot; a laser scanner installed on the gun body; a shielding gun fixed to the gun body in a first direction and shielding a laser beam irradiated from the laser scanner; and a pressing gun installed at the gun body to move in the first direction or in a second direction perpendicular to the first direction.

An apparatus includes a substrate and first and second electrical connectors. The apparatus also includes at least one first conductive trace positioned in, on, or over the substrate. The at least one first conductive trace forms an electrical connection between the first and second electrical connectors. The at least one first conductive trace is configured to be damaged by laser energy to break the electrical connection between the first and second electrical connectors. The apparatus further includes an indicator electrically coupled to the at least one first conductive trace. The indicator is configured to generate feedback based on whether the electrical connection between the first and second electrical connectors has been broken.